Maximizing Design Reliability with Advanced Linting: Uncover Hidden RTL Issues Early (EU)

LIVE WEBINAR SERIES:

Maximizing Design Reliability with Advanced Linting: Uncover Hidden RTL Issues Early (EU)

Alex Gnusin, Aldec’s ALINT-PRO Product Manager

Thursday, March 13, 2025

4:00 PM - 5:00 PM (CET)

Abstract:

Undetected RTL coding issues can lead to costly design iterations and unexpected failures late in the development cycle. Advanced linting is a powerful static analysis technique that detects bugs, inefficiencies, and structural issues in RTL code—long before they manifest in hardware.

Linting tools analyze HDL code against hundreds of industry-proven design rules, covering syntax, naming conventions, synthesizability, and performance optimizations. They also help detect clock domain crossing (CDC) issues, reset tree problems, and RTL-to-synthesis mismatches—errors that often remain invisible in functional simulations but can cause failures in FPGA lab testing.

In this webinar, we’ll explore the key benefits and best practices of advanced linting for robust and efficient design development. Through practical examples, we’ll demonstrate how linting can improve code quality, enhance design reuse, and prevent late-stage surprises.

Agenda:

Overview of the Advanced Linting Process
Best Practices for Effective Linting in RTL Design
Real-World Linting Examples:
- Identifying functional bugs early
- Optimizing code for synthesis and implementation
- Enhancing design quality and reusability
- Detecting clock/reset tree and CDC issues
Key Takeaways & Q&A

Webinar Duration

45 min presentation/live demo
15 min Q&A

Join us to learn how advanced linting can streamline your design process, reduce debugging time, and improve overall design reliability.

Presenter Bio:

Janusz Kitel is the DO-254 program manager at Aldec with over 18 years of experience in software and hardware design and verification.

Alex Gnusin,

Aldec’s ALINT-PRO Product Manager

Alex accumulated 27 years of hands-on experience in various aspects of ASIC and FPGA design and verification. As a verification prime for a multi-million gates project in companies such as IBM, Nortel, Ericsson and Synopsys Inc, he combined various verification methods such as static linting, formal property checking, dynamic simulation and hardware-assisted acceleration to efficiently achieve design verification goals. He received his M.S. in Electronics from Technion, Israel Institute of Technology.